1. Colour Vision I The retinal basis of colour vision and the inherited colour vision deficiencies Prof. Kathy T. Mullen McGill Vision Research (H4.14) Dept. of Ophthalmology kathy.mullen@mcgill.ca 8th Sept 2005

2. What is colour? What physical aspect of the world does our sense of colour inform us about?

3. Spectral colors 425 500 550 600 650 Violet Indigo Blue Green Yellow Orange Red Wavelength (nm)

4. Reflectance curves of some common foods Reflectance (percent) Wavelength (nm) Lemon Tomato Orange Cabbage

5. The colour circle

6. What is colour? Colour vision allows us to distinguish between surfaces with different spectral reflectances

7. How do we see colour?

8. White light is produced by mixing three colours

9. Mixing red and green lights to match yellow. ABC A and B. Green and red lights on the top are mixed by the subject to match the yellow light presented on the bottom. C. The red-green mixture perfectly matches the yellow. The same match as it appears to a deuteranomalous observer.

10. Principle of Trichromacy Mixing together three coloured lights in suitable proportions enables us to make an exact match to any other colour The 3 mixing lights are called ‘primaries’ The match is called ‘metameric’ - meaning that identical colour sensations are produced even though the stimuli are physically different 3 mixing lights test light to be matched L1 + L2 + L3 L4

11. Spectral sensitivities of L, M & S cones Wavelength (nm) Log relative sensitivity Long Medium Short

12. A single type of photoreceptor cannot signal colour Relative absorbance % 100 50 450550 (nm) L1L2

13. Response curve for a single receptor Relative absorbance % Wavelength (nm) L1L2 L1 = 2 (L2)

14. Principle of Univariance The response of a photoreceptor to any wavelength can be matched to any other wavelength simply by adjusting the relative intensities of the two stimuli Therefore: any single receptor type is colour blind

15. Response curve for a two receptor system Cone 1Cone 2 540 565 Wavelength relative absorbance % 100

16. How is colour coded? Each colour produces a unique pattern of relative activities in the three cone types

17. The basis of colour mixing in a two receptor (dichromatic) system ML L1L2 L3 WL (nm) 100 50 0 M L L:M L1 L2 L1+L2L3 Relative absorbancy Receptors Lights The mixture of red and green light looks the same as the yellow light because the red-green mixture and the yellow produce the same quantal absorptions in the L and M cones A dichromatic system requires 2 mixing lights A trichromatic (three receptor) system requires 3 mixing lights (primaries) 9055145 5095145 1:1 95 1:1

18. Colours with different wavelength distributions will look identical if they produce the same ratio of quantum catches in the L, M and S cone types

19. Metameric (matched) colour pairs for colour deficient observers

20. Inherited color vision deficiencies Systematic and predictable losses Both eyes affected Male - sex linked for L & M (red-green) deficiencies Genetic S cone deficiencies are autosomal and rare - many are undetected Color vision tests may not detect achromats

21. Trichromats One of the three cone types is anomalous

22. Trichromats Three colours are required to match any other See a full range of colours, but with poorer discrimination in some regions Types Protanomalous = anomalous L cones 1% (m) Deuteranomalous = anomalous M cones 5%(m) ‘Tritanomalous’ = incidence unknown

23. Dichromats One of the three cone types is missing

24. Dichromats Only need two colours to match any other Sees a much reduced range of colours Types Protanope = lacks L cones 1% (male) Deuteranope = lacks M cones 1% (male) Tritanope = lacks S cones 0.002%

25. Genes for the L & M cone pigments

26. Monochromats No colour vision: any colour matched with any other Rod monochromat (0.003%) All cones are functionally absent Blue cone monochromat (atypical monochromat) Only S cones are present (0.001%) Difficult to differentiate the two types May use colour names effectively May perform OK on some standard colour tests

28. Original Tritanope Deuteranope Protanope

29. Original Tritanope Deuteranope Protanope

30. Visual scene as it appears to (a) normal and (b-d) colour deficient observers

31. L/M cone opponent mechanisms

32. The luminance mechanism

33. Contrast sensitivity of red/green and luminance gratings red/green luminance

34. S/(L+M) cone opponent mechanisms